mirror of https://gitee.com/openkylin/linux.git
1122 lines
41 KiB
Plaintext
1122 lines
41 KiB
Plaintext
User Interface for Resource Control feature
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Intel refers to this feature as Intel Resource Director Technology(Intel(R) RDT).
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AMD refers to this feature as AMD Platform Quality of Service(AMD QoS).
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Copyright (C) 2016 Intel Corporation
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Fenghua Yu <fenghua.yu@intel.com>
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Tony Luck <tony.luck@intel.com>
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Vikas Shivappa <vikas.shivappa@intel.com>
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This feature is enabled by the CONFIG_X86_CPU_RESCTRL and the x86 /proc/cpuinfo
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flag bits:
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RDT (Resource Director Technology) Allocation - "rdt_a"
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CAT (Cache Allocation Technology) - "cat_l3", "cat_l2"
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CDP (Code and Data Prioritization ) - "cdp_l3", "cdp_l2"
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CQM (Cache QoS Monitoring) - "cqm_llc", "cqm_occup_llc"
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MBM (Memory Bandwidth Monitoring) - "cqm_mbm_total", "cqm_mbm_local"
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MBA (Memory Bandwidth Allocation) - "mba"
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To use the feature mount the file system:
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# mount -t resctrl resctrl [-o cdp[,cdpl2][,mba_MBps]] /sys/fs/resctrl
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mount options are:
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"cdp": Enable code/data prioritization in L3 cache allocations.
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"cdpl2": Enable code/data prioritization in L2 cache allocations.
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"mba_MBps": Enable the MBA Software Controller(mba_sc) to specify MBA
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bandwidth in MBps
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L2 and L3 CDP are controlled seperately.
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RDT features are orthogonal. A particular system may support only
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monitoring, only control, or both monitoring and control. Cache
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pseudo-locking is a unique way of using cache control to "pin" or
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"lock" data in the cache. Details can be found in
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"Cache Pseudo-Locking".
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The mount succeeds if either of allocation or monitoring is present, but
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only those files and directories supported by the system will be created.
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For more details on the behavior of the interface during monitoring
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and allocation, see the "Resource alloc and monitor groups" section.
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Info directory
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--------------
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The 'info' directory contains information about the enabled
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resources. Each resource has its own subdirectory. The subdirectory
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names reflect the resource names.
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Each subdirectory contains the following files with respect to
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allocation:
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Cache resource(L3/L2) subdirectory contains the following files
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related to allocation:
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"num_closids": The number of CLOSIDs which are valid for this
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resource. The kernel uses the smallest number of
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CLOSIDs of all enabled resources as limit.
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"cbm_mask": The bitmask which is valid for this resource.
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This mask is equivalent to 100%.
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"min_cbm_bits": The minimum number of consecutive bits which
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must be set when writing a mask.
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"shareable_bits": Bitmask of shareable resource with other executing
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entities (e.g. I/O). User can use this when
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setting up exclusive cache partitions. Note that
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some platforms support devices that have their
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own settings for cache use which can over-ride
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these bits.
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"bit_usage": Annotated capacity bitmasks showing how all
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instances of the resource are used. The legend is:
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"0" - Corresponding region is unused. When the system's
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resources have been allocated and a "0" is found
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in "bit_usage" it is a sign that resources are
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wasted.
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"H" - Corresponding region is used by hardware only
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but available for software use. If a resource
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has bits set in "shareable_bits" but not all
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of these bits appear in the resource groups'
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schematas then the bits appearing in
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"shareable_bits" but no resource group will
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be marked as "H".
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"X" - Corresponding region is available for sharing and
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used by hardware and software. These are the
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bits that appear in "shareable_bits" as
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well as a resource group's allocation.
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"S" - Corresponding region is used by software
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and available for sharing.
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"E" - Corresponding region is used exclusively by
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one resource group. No sharing allowed.
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"P" - Corresponding region is pseudo-locked. No
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sharing allowed.
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Memory bandwitdh(MB) subdirectory contains the following files
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with respect to allocation:
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"min_bandwidth": The minimum memory bandwidth percentage which
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user can request.
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"bandwidth_gran": The granularity in which the memory bandwidth
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percentage is allocated. The allocated
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b/w percentage is rounded off to the next
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control step available on the hardware. The
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available bandwidth control steps are:
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min_bandwidth + N * bandwidth_gran.
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"delay_linear": Indicates if the delay scale is linear or
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non-linear. This field is purely informational
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only.
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If RDT monitoring is available there will be an "L3_MON" directory
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with the following files:
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"num_rmids": The number of RMIDs available. This is the
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upper bound for how many "CTRL_MON" + "MON"
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groups can be created.
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"mon_features": Lists the monitoring events if
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monitoring is enabled for the resource.
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"max_threshold_occupancy":
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Read/write file provides the largest value (in
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bytes) at which a previously used LLC_occupancy
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counter can be considered for re-use.
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Finally, in the top level of the "info" directory there is a file
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named "last_cmd_status". This is reset with every "command" issued
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via the file system (making new directories or writing to any of the
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control files). If the command was successful, it will read as "ok".
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If the command failed, it will provide more information that can be
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conveyed in the error returns from file operations. E.g.
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# echo L3:0=f7 > schemata
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bash: echo: write error: Invalid argument
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# cat info/last_cmd_status
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mask f7 has non-consecutive 1-bits
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Resource alloc and monitor groups
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---------------------------------
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Resource groups are represented as directories in the resctrl file
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system. The default group is the root directory which, immediately
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after mounting, owns all the tasks and cpus in the system and can make
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full use of all resources.
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On a system with RDT control features additional directories can be
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created in the root directory that specify different amounts of each
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resource (see "schemata" below). The root and these additional top level
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directories are referred to as "CTRL_MON" groups below.
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On a system with RDT monitoring the root directory and other top level
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directories contain a directory named "mon_groups" in which additional
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directories can be created to monitor subsets of tasks in the CTRL_MON
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group that is their ancestor. These are called "MON" groups in the rest
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of this document.
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Removing a directory will move all tasks and cpus owned by the group it
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represents to the parent. Removing one of the created CTRL_MON groups
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will automatically remove all MON groups below it.
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All groups contain the following files:
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"tasks":
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Reading this file shows the list of all tasks that belong to
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this group. Writing a task id to the file will add a task to the
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group. If the group is a CTRL_MON group the task is removed from
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whichever previous CTRL_MON group owned the task and also from
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any MON group that owned the task. If the group is a MON group,
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then the task must already belong to the CTRL_MON parent of this
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group. The task is removed from any previous MON group.
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"cpus":
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Reading this file shows a bitmask of the logical CPUs owned by
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this group. Writing a mask to this file will add and remove
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CPUs to/from this group. As with the tasks file a hierarchy is
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maintained where MON groups may only include CPUs owned by the
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parent CTRL_MON group.
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When the resouce group is in pseudo-locked mode this file will
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only be readable, reflecting the CPUs associated with the
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pseudo-locked region.
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"cpus_list":
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Just like "cpus", only using ranges of CPUs instead of bitmasks.
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When control is enabled all CTRL_MON groups will also contain:
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"schemata":
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A list of all the resources available to this group.
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Each resource has its own line and format - see below for details.
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"size":
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Mirrors the display of the "schemata" file to display the size in
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bytes of each allocation instead of the bits representing the
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allocation.
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"mode":
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The "mode" of the resource group dictates the sharing of its
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allocations. A "shareable" resource group allows sharing of its
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allocations while an "exclusive" resource group does not. A
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cache pseudo-locked region is created by first writing
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"pseudo-locksetup" to the "mode" file before writing the cache
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pseudo-locked region's schemata to the resource group's "schemata"
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file. On successful pseudo-locked region creation the mode will
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automatically change to "pseudo-locked".
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When monitoring is enabled all MON groups will also contain:
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"mon_data":
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This contains a set of files organized by L3 domain and by
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RDT event. E.g. on a system with two L3 domains there will
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be subdirectories "mon_L3_00" and "mon_L3_01". Each of these
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directories have one file per event (e.g. "llc_occupancy",
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"mbm_total_bytes", and "mbm_local_bytes"). In a MON group these
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files provide a read out of the current value of the event for
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all tasks in the group. In CTRL_MON groups these files provide
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the sum for all tasks in the CTRL_MON group and all tasks in
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MON groups. Please see example section for more details on usage.
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Resource allocation rules
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-------------------------
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When a task is running the following rules define which resources are
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available to it:
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1) If the task is a member of a non-default group, then the schemata
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for that group is used.
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2) Else if the task belongs to the default group, but is running on a
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CPU that is assigned to some specific group, then the schemata for the
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CPU's group is used.
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3) Otherwise the schemata for the default group is used.
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Resource monitoring rules
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-------------------------
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1) If a task is a member of a MON group, or non-default CTRL_MON group
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then RDT events for the task will be reported in that group.
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2) If a task is a member of the default CTRL_MON group, but is running
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on a CPU that is assigned to some specific group, then the RDT events
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for the task will be reported in that group.
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3) Otherwise RDT events for the task will be reported in the root level
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"mon_data" group.
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Notes on cache occupancy monitoring and control
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-----------------------------------------------
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When moving a task from one group to another you should remember that
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this only affects *new* cache allocations by the task. E.g. you may have
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a task in a monitor group showing 3 MB of cache occupancy. If you move
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to a new group and immediately check the occupancy of the old and new
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groups you will likely see that the old group is still showing 3 MB and
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the new group zero. When the task accesses locations still in cache from
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before the move, the h/w does not update any counters. On a busy system
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you will likely see the occupancy in the old group go down as cache lines
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are evicted and re-used while the occupancy in the new group rises as
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the task accesses memory and loads into the cache are counted based on
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membership in the new group.
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The same applies to cache allocation control. Moving a task to a group
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with a smaller cache partition will not evict any cache lines. The
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process may continue to use them from the old partition.
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Hardware uses CLOSid(Class of service ID) and an RMID(Resource monitoring ID)
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to identify a control group and a monitoring group respectively. Each of
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the resource groups are mapped to these IDs based on the kind of group. The
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number of CLOSid and RMID are limited by the hardware and hence the creation of
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a "CTRL_MON" directory may fail if we run out of either CLOSID or RMID
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and creation of "MON" group may fail if we run out of RMIDs.
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max_threshold_occupancy - generic concepts
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------------------------------------------
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Note that an RMID once freed may not be immediately available for use as
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the RMID is still tagged the cache lines of the previous user of RMID.
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Hence such RMIDs are placed on limbo list and checked back if the cache
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occupancy has gone down. If there is a time when system has a lot of
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limbo RMIDs but which are not ready to be used, user may see an -EBUSY
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during mkdir.
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max_threshold_occupancy is a user configurable value to determine the
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occupancy at which an RMID can be freed.
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Schemata files - general concepts
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---------------------------------
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Each line in the file describes one resource. The line starts with
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the name of the resource, followed by specific values to be applied
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in each of the instances of that resource on the system.
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Cache IDs
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---------
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On current generation systems there is one L3 cache per socket and L2
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caches are generally just shared by the hyperthreads on a core, but this
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isn't an architectural requirement. We could have multiple separate L3
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caches on a socket, multiple cores could share an L2 cache. So instead
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of using "socket" or "core" to define the set of logical cpus sharing
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a resource we use a "Cache ID". At a given cache level this will be a
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unique number across the whole system (but it isn't guaranteed to be a
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contiguous sequence, there may be gaps). To find the ID for each logical
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CPU look in /sys/devices/system/cpu/cpu*/cache/index*/id
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Cache Bit Masks (CBM)
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---------------------
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For cache resources we describe the portion of the cache that is available
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for allocation using a bitmask. The maximum value of the mask is defined
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by each cpu model (and may be different for different cache levels). It
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is found using CPUID, but is also provided in the "info" directory of
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the resctrl file system in "info/{resource}/cbm_mask". X86 hardware
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requires that these masks have all the '1' bits in a contiguous block. So
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0x3, 0x6 and 0xC are legal 4-bit masks with two bits set, but 0x5, 0x9
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and 0xA are not. On a system with a 20-bit mask each bit represents 5%
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of the capacity of the cache. You could partition the cache into four
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equal parts with masks: 0x1f, 0x3e0, 0x7c00, 0xf8000.
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Memory bandwidth Allocation and monitoring
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------------------------------------------
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For Memory bandwidth resource, by default the user controls the resource
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by indicating the percentage of total memory bandwidth.
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The minimum bandwidth percentage value for each cpu model is predefined
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and can be looked up through "info/MB/min_bandwidth". The bandwidth
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granularity that is allocated is also dependent on the cpu model and can
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be looked up at "info/MB/bandwidth_gran". The available bandwidth
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control steps are: min_bw + N * bw_gran. Intermediate values are rounded
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to the next control step available on the hardware.
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The bandwidth throttling is a core specific mechanism on some of Intel
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SKUs. Using a high bandwidth and a low bandwidth setting on two threads
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sharing a core will result in both threads being throttled to use the
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low bandwidth. The fact that Memory bandwidth allocation(MBA) is a core
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specific mechanism where as memory bandwidth monitoring(MBM) is done at
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the package level may lead to confusion when users try to apply control
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via the MBA and then monitor the bandwidth to see if the controls are
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effective. Below are such scenarios:
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1. User may *not* see increase in actual bandwidth when percentage
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values are increased:
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This can occur when aggregate L2 external bandwidth is more than L3
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external bandwidth. Consider an SKL SKU with 24 cores on a package and
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where L2 external is 10GBps (hence aggregate L2 external bandwidth is
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240GBps) and L3 external bandwidth is 100GBps. Now a workload with '20
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threads, having 50% bandwidth, each consuming 5GBps' consumes the max L3
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bandwidth of 100GBps although the percentage value specified is only 50%
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<< 100%. Hence increasing the bandwidth percentage will not yeild any
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more bandwidth. This is because although the L2 external bandwidth still
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has capacity, the L3 external bandwidth is fully used. Also note that
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this would be dependent on number of cores the benchmark is run on.
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2. Same bandwidth percentage may mean different actual bandwidth
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depending on # of threads:
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For the same SKU in #1, a 'single thread, with 10% bandwidth' and '4
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thread, with 10% bandwidth' can consume upto 10GBps and 40GBps although
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they have same percentage bandwidth of 10%. This is simply because as
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threads start using more cores in an rdtgroup, the actual bandwidth may
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increase or vary although user specified bandwidth percentage is same.
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In order to mitigate this and make the interface more user friendly,
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resctrl added support for specifying the bandwidth in MBps as well. The
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kernel underneath would use a software feedback mechanism or a "Software
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Controller(mba_sc)" which reads the actual bandwidth using MBM counters
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and adjust the memowy bandwidth percentages to ensure
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"actual bandwidth < user specified bandwidth".
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By default, the schemata would take the bandwidth percentage values
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where as user can switch to the "MBA software controller" mode using
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a mount option 'mba_MBps'. The schemata format is specified in the below
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sections.
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L3 schemata file details (code and data prioritization disabled)
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----------------------------------------------------------------
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With CDP disabled the L3 schemata format is:
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L3:<cache_id0>=<cbm>;<cache_id1>=<cbm>;...
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L3 schemata file details (CDP enabled via mount option to resctrl)
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------------------------------------------------------------------
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When CDP is enabled L3 control is split into two separate resources
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so you can specify independent masks for code and data like this:
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L3data:<cache_id0>=<cbm>;<cache_id1>=<cbm>;...
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L3code:<cache_id0>=<cbm>;<cache_id1>=<cbm>;...
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L2 schemata file details
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------------------------
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L2 cache does not support code and data prioritization, so the
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schemata format is always:
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L2:<cache_id0>=<cbm>;<cache_id1>=<cbm>;...
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Memory bandwidth Allocation (default mode)
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------------------------------------------
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Memory b/w domain is L3 cache.
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MB:<cache_id0>=bandwidth0;<cache_id1>=bandwidth1;...
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Memory bandwidth Allocation specified in MBps
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---------------------------------------------
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Memory bandwidth domain is L3 cache.
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MB:<cache_id0>=bw_MBps0;<cache_id1>=bw_MBps1;...
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Reading/writing the schemata file
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---------------------------------
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Reading the schemata file will show the state of all resources
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on all domains. When writing you only need to specify those values
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which you wish to change. E.g.
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# cat schemata
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L3DATA:0=fffff;1=fffff;2=fffff;3=fffff
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L3CODE:0=fffff;1=fffff;2=fffff;3=fffff
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# echo "L3DATA:2=3c0;" > schemata
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# cat schemata
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L3DATA:0=fffff;1=fffff;2=3c0;3=fffff
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L3CODE:0=fffff;1=fffff;2=fffff;3=fffff
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Cache Pseudo-Locking
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--------------------
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CAT enables a user to specify the amount of cache space that an
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application can fill. Cache pseudo-locking builds on the fact that a
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CPU can still read and write data pre-allocated outside its current
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allocated area on a cache hit. With cache pseudo-locking, data can be
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preloaded into a reserved portion of cache that no application can
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fill, and from that point on will only serve cache hits. The cache
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pseudo-locked memory is made accessible to user space where an
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application can map it into its virtual address space and thus have
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a region of memory with reduced average read latency.
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The creation of a cache pseudo-locked region is triggered by a request
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from the user to do so that is accompanied by a schemata of the region
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to be pseudo-locked. The cache pseudo-locked region is created as follows:
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- Create a CAT allocation CLOSNEW with a CBM matching the schemata
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from the user of the cache region that will contain the pseudo-locked
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memory. This region must not overlap with any current CAT allocation/CLOS
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on the system and no future overlap with this cache region is allowed
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while the pseudo-locked region exists.
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- Create a contiguous region of memory of the same size as the cache
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region.
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- Flush the cache, disable hardware prefetchers, disable preemption.
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- Make CLOSNEW the active CLOS and touch the allocated memory to load
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it into the cache.
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- Set the previous CLOS as active.
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- At this point the closid CLOSNEW can be released - the cache
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pseudo-locked region is protected as long as its CBM does not appear in
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any CAT allocation. Even though the cache pseudo-locked region will from
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this point on not appear in any CBM of any CLOS an application running with
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any CLOS will be able to access the memory in the pseudo-locked region since
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the region continues to serve cache hits.
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- The contiguous region of memory loaded into the cache is exposed to
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user-space as a character device.
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Cache pseudo-locking increases the probability that data will remain
|
|
in the cache via carefully configuring the CAT feature and controlling
|
|
application behavior. There is no guarantee that data is placed in
|
|
cache. Instructions like INVD, WBINVD, CLFLUSH, etc. can still evict
|
|
“locked” data from cache. Power management C-states may shrink or
|
|
power off cache. Deeper C-states will automatically be restricted on
|
|
pseudo-locked region creation.
|
|
|
|
It is required that an application using a pseudo-locked region runs
|
|
with affinity to the cores (or a subset of the cores) associated
|
|
with the cache on which the pseudo-locked region resides. A sanity check
|
|
within the code will not allow an application to map pseudo-locked memory
|
|
unless it runs with affinity to cores associated with the cache on which the
|
|
pseudo-locked region resides. The sanity check is only done during the
|
|
initial mmap() handling, there is no enforcement afterwards and the
|
|
application self needs to ensure it remains affine to the correct cores.
|
|
|
|
Pseudo-locking is accomplished in two stages:
|
|
1) During the first stage the system administrator allocates a portion
|
|
of cache that should be dedicated to pseudo-locking. At this time an
|
|
equivalent portion of memory is allocated, loaded into allocated
|
|
cache portion, and exposed as a character device.
|
|
2) During the second stage a user-space application maps (mmap()) the
|
|
pseudo-locked memory into its address space.
|
|
|
|
Cache Pseudo-Locking Interface
|
|
------------------------------
|
|
A pseudo-locked region is created using the resctrl interface as follows:
|
|
|
|
1) Create a new resource group by creating a new directory in /sys/fs/resctrl.
|
|
2) Change the new resource group's mode to "pseudo-locksetup" by writing
|
|
"pseudo-locksetup" to the "mode" file.
|
|
3) Write the schemata of the pseudo-locked region to the "schemata" file. All
|
|
bits within the schemata should be "unused" according to the "bit_usage"
|
|
file.
|
|
|
|
On successful pseudo-locked region creation the "mode" file will contain
|
|
"pseudo-locked" and a new character device with the same name as the resource
|
|
group will exist in /dev/pseudo_lock. This character device can be mmap()'ed
|
|
by user space in order to obtain access to the pseudo-locked memory region.
|
|
|
|
An example of cache pseudo-locked region creation and usage can be found below.
|
|
|
|
Cache Pseudo-Locking Debugging Interface
|
|
---------------------------------------
|
|
The pseudo-locking debugging interface is enabled by default (if
|
|
CONFIG_DEBUG_FS is enabled) and can be found in /sys/kernel/debug/resctrl.
|
|
|
|
There is no explicit way for the kernel to test if a provided memory
|
|
location is present in the cache. The pseudo-locking debugging interface uses
|
|
the tracing infrastructure to provide two ways to measure cache residency of
|
|
the pseudo-locked region:
|
|
1) Memory access latency using the pseudo_lock_mem_latency tracepoint. Data
|
|
from these measurements are best visualized using a hist trigger (see
|
|
example below). In this test the pseudo-locked region is traversed at
|
|
a stride of 32 bytes while hardware prefetchers and preemption
|
|
are disabled. This also provides a substitute visualization of cache
|
|
hits and misses.
|
|
2) Cache hit and miss measurements using model specific precision counters if
|
|
available. Depending on the levels of cache on the system the pseudo_lock_l2
|
|
and pseudo_lock_l3 tracepoints are available.
|
|
|
|
When a pseudo-locked region is created a new debugfs directory is created for
|
|
it in debugfs as /sys/kernel/debug/resctrl/<newdir>. A single
|
|
write-only file, pseudo_lock_measure, is present in this directory. The
|
|
measurement of the pseudo-locked region depends on the number written to this
|
|
debugfs file:
|
|
1 - writing "1" to the pseudo_lock_measure file will trigger the latency
|
|
measurement captured in the pseudo_lock_mem_latency tracepoint. See
|
|
example below.
|
|
2 - writing "2" to the pseudo_lock_measure file will trigger the L2 cache
|
|
residency (cache hits and misses) measurement captured in the
|
|
pseudo_lock_l2 tracepoint. See example below.
|
|
3 - writing "3" to the pseudo_lock_measure file will trigger the L3 cache
|
|
residency (cache hits and misses) measurement captured in the
|
|
pseudo_lock_l3 tracepoint.
|
|
|
|
All measurements are recorded with the tracing infrastructure. This requires
|
|
the relevant tracepoints to be enabled before the measurement is triggered.
|
|
|
|
Example of latency debugging interface:
|
|
In this example a pseudo-locked region named "newlock" was created. Here is
|
|
how we can measure the latency in cycles of reading from this region and
|
|
visualize this data with a histogram that is available if CONFIG_HIST_TRIGGERS
|
|
is set:
|
|
# :> /sys/kernel/debug/tracing/trace
|
|
# echo 'hist:keys=latency' > /sys/kernel/debug/tracing/events/resctrl/pseudo_lock_mem_latency/trigger
|
|
# echo 1 > /sys/kernel/debug/tracing/events/resctrl/pseudo_lock_mem_latency/enable
|
|
# echo 1 > /sys/kernel/debug/resctrl/newlock/pseudo_lock_measure
|
|
# echo 0 > /sys/kernel/debug/tracing/events/resctrl/pseudo_lock_mem_latency/enable
|
|
# cat /sys/kernel/debug/tracing/events/resctrl/pseudo_lock_mem_latency/hist
|
|
|
|
# event histogram
|
|
#
|
|
# trigger info: hist:keys=latency:vals=hitcount:sort=hitcount:size=2048 [active]
|
|
#
|
|
|
|
{ latency: 456 } hitcount: 1
|
|
{ latency: 50 } hitcount: 83
|
|
{ latency: 36 } hitcount: 96
|
|
{ latency: 44 } hitcount: 174
|
|
{ latency: 48 } hitcount: 195
|
|
{ latency: 46 } hitcount: 262
|
|
{ latency: 42 } hitcount: 693
|
|
{ latency: 40 } hitcount: 3204
|
|
{ latency: 38 } hitcount: 3484
|
|
|
|
Totals:
|
|
Hits: 8192
|
|
Entries: 9
|
|
Dropped: 0
|
|
|
|
Example of cache hits/misses debugging:
|
|
In this example a pseudo-locked region named "newlock" was created on the L2
|
|
cache of a platform. Here is how we can obtain details of the cache hits
|
|
and misses using the platform's precision counters.
|
|
|
|
# :> /sys/kernel/debug/tracing/trace
|
|
# echo 1 > /sys/kernel/debug/tracing/events/resctrl/pseudo_lock_l2/enable
|
|
# echo 2 > /sys/kernel/debug/resctrl/newlock/pseudo_lock_measure
|
|
# echo 0 > /sys/kernel/debug/tracing/events/resctrl/pseudo_lock_l2/enable
|
|
# cat /sys/kernel/debug/tracing/trace
|
|
|
|
# tracer: nop
|
|
#
|
|
# _-----=> irqs-off
|
|
# / _----=> need-resched
|
|
# | / _---=> hardirq/softirq
|
|
# || / _--=> preempt-depth
|
|
# ||| / delay
|
|
# TASK-PID CPU# |||| TIMESTAMP FUNCTION
|
|
# | | | |||| | |
|
|
pseudo_lock_mea-1672 [002] .... 3132.860500: pseudo_lock_l2: hits=4097 miss=0
|
|
|
|
|
|
Examples for RDT allocation usage:
|
|
|
|
Example 1
|
|
---------
|
|
On a two socket machine (one L3 cache per socket) with just four bits
|
|
for cache bit masks, minimum b/w of 10% with a memory bandwidth
|
|
granularity of 10%
|
|
|
|
# mount -t resctrl resctrl /sys/fs/resctrl
|
|
# cd /sys/fs/resctrl
|
|
# mkdir p0 p1
|
|
# echo "L3:0=3;1=c\nMB:0=50;1=50" > /sys/fs/resctrl/p0/schemata
|
|
# echo "L3:0=3;1=3\nMB:0=50;1=50" > /sys/fs/resctrl/p1/schemata
|
|
|
|
The default resource group is unmodified, so we have access to all parts
|
|
of all caches (its schemata file reads "L3:0=f;1=f").
|
|
|
|
Tasks that are under the control of group "p0" may only allocate from the
|
|
"lower" 50% on cache ID 0, and the "upper" 50% of cache ID 1.
|
|
Tasks in group "p1" use the "lower" 50% of cache on both sockets.
|
|
|
|
Similarly, tasks that are under the control of group "p0" may use a
|
|
maximum memory b/w of 50% on socket0 and 50% on socket 1.
|
|
Tasks in group "p1" may also use 50% memory b/w on both sockets.
|
|
Note that unlike cache masks, memory b/w cannot specify whether these
|
|
allocations can overlap or not. The allocations specifies the maximum
|
|
b/w that the group may be able to use and the system admin can configure
|
|
the b/w accordingly.
|
|
|
|
If the MBA is specified in MB(megabytes) then user can enter the max b/w in MB
|
|
rather than the percentage values.
|
|
|
|
# echo "L3:0=3;1=c\nMB:0=1024;1=500" > /sys/fs/resctrl/p0/schemata
|
|
# echo "L3:0=3;1=3\nMB:0=1024;1=500" > /sys/fs/resctrl/p1/schemata
|
|
|
|
In the above example the tasks in "p1" and "p0" on socket 0 would use a max b/w
|
|
of 1024MB where as on socket 1 they would use 500MB.
|
|
|
|
Example 2
|
|
---------
|
|
Again two sockets, but this time with a more realistic 20-bit mask.
|
|
|
|
Two real time tasks pid=1234 running on processor 0 and pid=5678 running on
|
|
processor 1 on socket 0 on a 2-socket and dual core machine. To avoid noisy
|
|
neighbors, each of the two real-time tasks exclusively occupies one quarter
|
|
of L3 cache on socket 0.
|
|
|
|
# mount -t resctrl resctrl /sys/fs/resctrl
|
|
# cd /sys/fs/resctrl
|
|
|
|
First we reset the schemata for the default group so that the "upper"
|
|
50% of the L3 cache on socket 0 and 50% of memory b/w cannot be used by
|
|
ordinary tasks:
|
|
|
|
# echo "L3:0=3ff;1=fffff\nMB:0=50;1=100" > schemata
|
|
|
|
Next we make a resource group for our first real time task and give
|
|
it access to the "top" 25% of the cache on socket 0.
|
|
|
|
# mkdir p0
|
|
# echo "L3:0=f8000;1=fffff" > p0/schemata
|
|
|
|
Finally we move our first real time task into this resource group. We
|
|
also use taskset(1) to ensure the task always runs on a dedicated CPU
|
|
on socket 0. Most uses of resource groups will also constrain which
|
|
processors tasks run on.
|
|
|
|
# echo 1234 > p0/tasks
|
|
# taskset -cp 1 1234
|
|
|
|
Ditto for the second real time task (with the remaining 25% of cache):
|
|
|
|
# mkdir p1
|
|
# echo "L3:0=7c00;1=fffff" > p1/schemata
|
|
# echo 5678 > p1/tasks
|
|
# taskset -cp 2 5678
|
|
|
|
For the same 2 socket system with memory b/w resource and CAT L3 the
|
|
schemata would look like(Assume min_bandwidth 10 and bandwidth_gran is
|
|
10):
|
|
|
|
For our first real time task this would request 20% memory b/w on socket
|
|
0.
|
|
|
|
# echo -e "L3:0=f8000;1=fffff\nMB:0=20;1=100" > p0/schemata
|
|
|
|
For our second real time task this would request an other 20% memory b/w
|
|
on socket 0.
|
|
|
|
# echo -e "L3:0=f8000;1=fffff\nMB:0=20;1=100" > p0/schemata
|
|
|
|
Example 3
|
|
---------
|
|
|
|
A single socket system which has real-time tasks running on core 4-7 and
|
|
non real-time workload assigned to core 0-3. The real-time tasks share text
|
|
and data, so a per task association is not required and due to interaction
|
|
with the kernel it's desired that the kernel on these cores shares L3 with
|
|
the tasks.
|
|
|
|
# mount -t resctrl resctrl /sys/fs/resctrl
|
|
# cd /sys/fs/resctrl
|
|
|
|
First we reset the schemata for the default group so that the "upper"
|
|
50% of the L3 cache on socket 0, and 50% of memory bandwidth on socket 0
|
|
cannot be used by ordinary tasks:
|
|
|
|
# echo "L3:0=3ff\nMB:0=50" > schemata
|
|
|
|
Next we make a resource group for our real time cores and give it access
|
|
to the "top" 50% of the cache on socket 0 and 50% of memory bandwidth on
|
|
socket 0.
|
|
|
|
# mkdir p0
|
|
# echo "L3:0=ffc00\nMB:0=50" > p0/schemata
|
|
|
|
Finally we move core 4-7 over to the new group and make sure that the
|
|
kernel and the tasks running there get 50% of the cache. They should
|
|
also get 50% of memory bandwidth assuming that the cores 4-7 are SMT
|
|
siblings and only the real time threads are scheduled on the cores 4-7.
|
|
|
|
# echo F0 > p0/cpus
|
|
|
|
Example 4
|
|
---------
|
|
|
|
The resource groups in previous examples were all in the default "shareable"
|
|
mode allowing sharing of their cache allocations. If one resource group
|
|
configures a cache allocation then nothing prevents another resource group
|
|
to overlap with that allocation.
|
|
|
|
In this example a new exclusive resource group will be created on a L2 CAT
|
|
system with two L2 cache instances that can be configured with an 8-bit
|
|
capacity bitmask. The new exclusive resource group will be configured to use
|
|
25% of each cache instance.
|
|
|
|
# mount -t resctrl resctrl /sys/fs/resctrl/
|
|
# cd /sys/fs/resctrl
|
|
|
|
First, we observe that the default group is configured to allocate to all L2
|
|
cache:
|
|
|
|
# cat schemata
|
|
L2:0=ff;1=ff
|
|
|
|
We could attempt to create the new resource group at this point, but it will
|
|
fail because of the overlap with the schemata of the default group:
|
|
# mkdir p0
|
|
# echo 'L2:0=0x3;1=0x3' > p0/schemata
|
|
# cat p0/mode
|
|
shareable
|
|
# echo exclusive > p0/mode
|
|
-sh: echo: write error: Invalid argument
|
|
# cat info/last_cmd_status
|
|
schemata overlaps
|
|
|
|
To ensure that there is no overlap with another resource group the default
|
|
resource group's schemata has to change, making it possible for the new
|
|
resource group to become exclusive.
|
|
# echo 'L2:0=0xfc;1=0xfc' > schemata
|
|
# echo exclusive > p0/mode
|
|
# grep . p0/*
|
|
p0/cpus:0
|
|
p0/mode:exclusive
|
|
p0/schemata:L2:0=03;1=03
|
|
p0/size:L2:0=262144;1=262144
|
|
|
|
A new resource group will on creation not overlap with an exclusive resource
|
|
group:
|
|
# mkdir p1
|
|
# grep . p1/*
|
|
p1/cpus:0
|
|
p1/mode:shareable
|
|
p1/schemata:L2:0=fc;1=fc
|
|
p1/size:L2:0=786432;1=786432
|
|
|
|
The bit_usage will reflect how the cache is used:
|
|
# cat info/L2/bit_usage
|
|
0=SSSSSSEE;1=SSSSSSEE
|
|
|
|
A resource group cannot be forced to overlap with an exclusive resource group:
|
|
# echo 'L2:0=0x1;1=0x1' > p1/schemata
|
|
-sh: echo: write error: Invalid argument
|
|
# cat info/last_cmd_status
|
|
overlaps with exclusive group
|
|
|
|
Example of Cache Pseudo-Locking
|
|
-------------------------------
|
|
Lock portion of L2 cache from cache id 1 using CBM 0x3. Pseudo-locked
|
|
region is exposed at /dev/pseudo_lock/newlock that can be provided to
|
|
application for argument to mmap().
|
|
|
|
# mount -t resctrl resctrl /sys/fs/resctrl/
|
|
# cd /sys/fs/resctrl
|
|
|
|
Ensure that there are bits available that can be pseudo-locked, since only
|
|
unused bits can be pseudo-locked the bits to be pseudo-locked needs to be
|
|
removed from the default resource group's schemata:
|
|
# cat info/L2/bit_usage
|
|
0=SSSSSSSS;1=SSSSSSSS
|
|
# echo 'L2:1=0xfc' > schemata
|
|
# cat info/L2/bit_usage
|
|
0=SSSSSSSS;1=SSSSSS00
|
|
|
|
Create a new resource group that will be associated with the pseudo-locked
|
|
region, indicate that it will be used for a pseudo-locked region, and
|
|
configure the requested pseudo-locked region capacity bitmask:
|
|
|
|
# mkdir newlock
|
|
# echo pseudo-locksetup > newlock/mode
|
|
# echo 'L2:1=0x3' > newlock/schemata
|
|
|
|
On success the resource group's mode will change to pseudo-locked, the
|
|
bit_usage will reflect the pseudo-locked region, and the character device
|
|
exposing the pseudo-locked region will exist:
|
|
|
|
# cat newlock/mode
|
|
pseudo-locked
|
|
# cat info/L2/bit_usage
|
|
0=SSSSSSSS;1=SSSSSSPP
|
|
# ls -l /dev/pseudo_lock/newlock
|
|
crw------- 1 root root 243, 0 Apr 3 05:01 /dev/pseudo_lock/newlock
|
|
|
|
/*
|
|
* Example code to access one page of pseudo-locked cache region
|
|
* from user space.
|
|
*/
|
|
#define _GNU_SOURCE
|
|
#include <fcntl.h>
|
|
#include <sched.h>
|
|
#include <stdio.h>
|
|
#include <stdlib.h>
|
|
#include <unistd.h>
|
|
#include <sys/mman.h>
|
|
|
|
/*
|
|
* It is required that the application runs with affinity to only
|
|
* cores associated with the pseudo-locked region. Here the cpu
|
|
* is hardcoded for convenience of example.
|
|
*/
|
|
static int cpuid = 2;
|
|
|
|
int main(int argc, char *argv[])
|
|
{
|
|
cpu_set_t cpuset;
|
|
long page_size;
|
|
void *mapping;
|
|
int dev_fd;
|
|
int ret;
|
|
|
|
page_size = sysconf(_SC_PAGESIZE);
|
|
|
|
CPU_ZERO(&cpuset);
|
|
CPU_SET(cpuid, &cpuset);
|
|
ret = sched_setaffinity(0, sizeof(cpuset), &cpuset);
|
|
if (ret < 0) {
|
|
perror("sched_setaffinity");
|
|
exit(EXIT_FAILURE);
|
|
}
|
|
|
|
dev_fd = open("/dev/pseudo_lock/newlock", O_RDWR);
|
|
if (dev_fd < 0) {
|
|
perror("open");
|
|
exit(EXIT_FAILURE);
|
|
}
|
|
|
|
mapping = mmap(0, page_size, PROT_READ | PROT_WRITE, MAP_SHARED,
|
|
dev_fd, 0);
|
|
if (mapping == MAP_FAILED) {
|
|
perror("mmap");
|
|
close(dev_fd);
|
|
exit(EXIT_FAILURE);
|
|
}
|
|
|
|
/* Application interacts with pseudo-locked memory @mapping */
|
|
|
|
ret = munmap(mapping, page_size);
|
|
if (ret < 0) {
|
|
perror("munmap");
|
|
close(dev_fd);
|
|
exit(EXIT_FAILURE);
|
|
}
|
|
|
|
close(dev_fd);
|
|
exit(EXIT_SUCCESS);
|
|
}
|
|
|
|
Locking between applications
|
|
----------------------------
|
|
|
|
Certain operations on the resctrl filesystem, composed of read/writes
|
|
to/from multiple files, must be atomic.
|
|
|
|
As an example, the allocation of an exclusive reservation of L3 cache
|
|
involves:
|
|
|
|
1. Read the cbmmasks from each directory or the per-resource "bit_usage"
|
|
2. Find a contiguous set of bits in the global CBM bitmask that is clear
|
|
in any of the directory cbmmasks
|
|
3. Create a new directory
|
|
4. Set the bits found in step 2 to the new directory "schemata" file
|
|
|
|
If two applications attempt to allocate space concurrently then they can
|
|
end up allocating the same bits so the reservations are shared instead of
|
|
exclusive.
|
|
|
|
To coordinate atomic operations on the resctrlfs and to avoid the problem
|
|
above, the following locking procedure is recommended:
|
|
|
|
Locking is based on flock, which is available in libc and also as a shell
|
|
script command
|
|
|
|
Write lock:
|
|
|
|
A) Take flock(LOCK_EX) on /sys/fs/resctrl
|
|
B) Read/write the directory structure.
|
|
C) funlock
|
|
|
|
Read lock:
|
|
|
|
A) Take flock(LOCK_SH) on /sys/fs/resctrl
|
|
B) If success read the directory structure.
|
|
C) funlock
|
|
|
|
Example with bash:
|
|
|
|
# Atomically read directory structure
|
|
$ flock -s /sys/fs/resctrl/ find /sys/fs/resctrl
|
|
|
|
# Read directory contents and create new subdirectory
|
|
|
|
$ cat create-dir.sh
|
|
find /sys/fs/resctrl/ > output.txt
|
|
mask = function-of(output.txt)
|
|
mkdir /sys/fs/resctrl/newres/
|
|
echo mask > /sys/fs/resctrl/newres/schemata
|
|
|
|
$ flock /sys/fs/resctrl/ ./create-dir.sh
|
|
|
|
Example with C:
|
|
|
|
/*
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* Example code do take advisory locks
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* before accessing resctrl filesystem
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*/
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#include <sys/file.h>
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#include <stdlib.h>
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void resctrl_take_shared_lock(int fd)
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{
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int ret;
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/* take shared lock on resctrl filesystem */
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ret = flock(fd, LOCK_SH);
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if (ret) {
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perror("flock");
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exit(-1);
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}
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}
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void resctrl_take_exclusive_lock(int fd)
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{
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int ret;
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/* release lock on resctrl filesystem */
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ret = flock(fd, LOCK_EX);
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if (ret) {
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perror("flock");
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exit(-1);
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}
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}
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void resctrl_release_lock(int fd)
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{
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int ret;
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/* take shared lock on resctrl filesystem */
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ret = flock(fd, LOCK_UN);
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if (ret) {
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perror("flock");
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exit(-1);
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}
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}
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void main(void)
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{
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int fd, ret;
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fd = open("/sys/fs/resctrl", O_DIRECTORY);
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if (fd == -1) {
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perror("open");
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exit(-1);
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}
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resctrl_take_shared_lock(fd);
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/* code to read directory contents */
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resctrl_release_lock(fd);
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resctrl_take_exclusive_lock(fd);
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/* code to read and write directory contents */
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resctrl_release_lock(fd);
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}
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Examples for RDT Monitoring along with allocation usage:
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Reading monitored data
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----------------------
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Reading an event file (for ex: mon_data/mon_L3_00/llc_occupancy) would
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show the current snapshot of LLC occupancy of the corresponding MON
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group or CTRL_MON group.
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Example 1 (Monitor CTRL_MON group and subset of tasks in CTRL_MON group)
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---------
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On a two socket machine (one L3 cache per socket) with just four bits
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for cache bit masks
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# mount -t resctrl resctrl /sys/fs/resctrl
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# cd /sys/fs/resctrl
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# mkdir p0 p1
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# echo "L3:0=3;1=c" > /sys/fs/resctrl/p0/schemata
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# echo "L3:0=3;1=3" > /sys/fs/resctrl/p1/schemata
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# echo 5678 > p1/tasks
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# echo 5679 > p1/tasks
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The default resource group is unmodified, so we have access to all parts
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of all caches (its schemata file reads "L3:0=f;1=f").
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Tasks that are under the control of group "p0" may only allocate from the
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"lower" 50% on cache ID 0, and the "upper" 50% of cache ID 1.
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Tasks in group "p1" use the "lower" 50% of cache on both sockets.
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Create monitor groups and assign a subset of tasks to each monitor group.
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# cd /sys/fs/resctrl/p1/mon_groups
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# mkdir m11 m12
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# echo 5678 > m11/tasks
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# echo 5679 > m12/tasks
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fetch data (data shown in bytes)
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# cat m11/mon_data/mon_L3_00/llc_occupancy
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16234000
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# cat m11/mon_data/mon_L3_01/llc_occupancy
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14789000
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# cat m12/mon_data/mon_L3_00/llc_occupancy
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16789000
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The parent ctrl_mon group shows the aggregated data.
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# cat /sys/fs/resctrl/p1/mon_data/mon_l3_00/llc_occupancy
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31234000
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Example 2 (Monitor a task from its creation)
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---------
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On a two socket machine (one L3 cache per socket)
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# mount -t resctrl resctrl /sys/fs/resctrl
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# cd /sys/fs/resctrl
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# mkdir p0 p1
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An RMID is allocated to the group once its created and hence the <cmd>
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below is monitored from its creation.
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# echo $$ > /sys/fs/resctrl/p1/tasks
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# <cmd>
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Fetch the data
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# cat /sys/fs/resctrl/p1/mon_data/mon_l3_00/llc_occupancy
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31789000
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Example 3 (Monitor without CAT support or before creating CAT groups)
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---------
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Assume a system like HSW has only CQM and no CAT support. In this case
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the resctrl will still mount but cannot create CTRL_MON directories.
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But user can create different MON groups within the root group thereby
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able to monitor all tasks including kernel threads.
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This can also be used to profile jobs cache size footprint before being
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able to allocate them to different allocation groups.
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# mount -t resctrl resctrl /sys/fs/resctrl
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# cd /sys/fs/resctrl
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# mkdir mon_groups/m01
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# mkdir mon_groups/m02
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# echo 3478 > /sys/fs/resctrl/mon_groups/m01/tasks
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# echo 2467 > /sys/fs/resctrl/mon_groups/m02/tasks
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Monitor the groups separately and also get per domain data. From the
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below its apparent that the tasks are mostly doing work on
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domain(socket) 0.
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# cat /sys/fs/resctrl/mon_groups/m01/mon_L3_00/llc_occupancy
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31234000
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# cat /sys/fs/resctrl/mon_groups/m01/mon_L3_01/llc_occupancy
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34555
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# cat /sys/fs/resctrl/mon_groups/m02/mon_L3_00/llc_occupancy
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31234000
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# cat /sys/fs/resctrl/mon_groups/m02/mon_L3_01/llc_occupancy
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32789
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Example 4 (Monitor real time tasks)
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-----------------------------------
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A single socket system which has real time tasks running on cores 4-7
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and non real time tasks on other cpus. We want to monitor the cache
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occupancy of the real time threads on these cores.
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# mount -t resctrl resctrl /sys/fs/resctrl
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# cd /sys/fs/resctrl
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# mkdir p1
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Move the cpus 4-7 over to p1
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# echo f0 > p1/cpus
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View the llc occupancy snapshot
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# cat /sys/fs/resctrl/p1/mon_data/mon_L3_00/llc_occupancy
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11234000
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